Molecular markers as a complementary tool in risk assessments: quantifying interspecific gene flow from triticale to spring wheat and durum wheat.

Triticale is being considered as a bioindustrial crop in Canada using genetic modification. Because related spring wheat (Triticum aestivum) and durum wheat (T. durum) may exhibit synchronous flowering and grow in proximity, determination of interspecific gene flow when triticale is the pollen donor is necessary to evaluate potential risk. Pollen-mediated gene flow risk assessments generally rely on phenotypic markers to detect hybridization but DNA markers could be powerful and less ambiguous in quantifying rare interspecific gene flow. Six cultivars representing four species [spring wheat, durum wheat, triticale and rye (Secale cereale)] were screened with 235 spring wheat and 27 rye SSR markers to evaluate transferability and polymorphism. Fifty-five polymorphic markers were used in conjunction with morphological characterization to quantify interspecific gene flow from a blue aleurone (BA) triticale line to two spring wheat cultivars (AC Barrie and AC Crystal) and one durum wheat cultivar (AC Avonlea). Approximately 1.9 Million seeds from small plot experiments were visually screened in comparison with known hybrid seed. In total 2031 putative hybrids were identified and 448 germinated. Morphological analysis of putative hybrid plants identified five hybrids while molecular analysis identified 11 hybrids and two were common to both. Combined, 14 hybrids were confirmed: 10 spring wheat × triticale (0.0008 % of harvested seed): seven AC Barrie × BA triticale (0.001 %) and three AC Crystal × BA triticale (0.0005 %); and four durum wheat × triticale (0.0006 %). The occurrence of rare hybrids does not present a substantial risk to the development of GM triticale.

Pollen-mediated gene flow from transgenic safflower (Carthamus tinctorius L.) intended for plant molecular farming to conventional safflower.

Field experiments were conducted in Chile and western Canada to measure short-distance (0 to 100 m) outcrossing from transgenic safflower (Carthamus tinctorius L.) intended for plant molecular farming to non-transgenic commodity safflower of the same variety. The transgenic safflower used as the pollen source was transformed with a construct for seed-specific expression of a high-value protein and constitutive expression of a gene conferring resistance to the broad-spectrum herbicide glufosinate. Progeny of non-transgenic plants grown in plots adjacent to the transgenic pollen source were screened for glufosinate resistance to measure outcrossing frequency. Outcrossing frequency differed among locations: values closest to the transgenic pollen source (0 to 3 m) ranged from 0.48 to 1.67% and rapidly declined to between 0.0024 to 0.03% at distances of 50 to 100 m. At each location, outcrossing frequency was spatially heterogeneous, indicating insects or wind moved pollen asymmetrically. A power analysis assuming a binomial distribution and a range of alpha values (type 1 error) was conducted to estimate an upper and lower confidence interval for the probable transgenic seed frequency in each sample. This facilitated interpretation when large numbers of seeds were screened from the outcrossing experiments and no transgenic seeds were found. This study should aid regulators and the plant molecular farming industry in developing confinement strategies to mitigate pollen mediated gene flow from transgenic to non-transgenic safflower.